System for electrical connection of printed circuit boards and backplanes in server enclosure

ABSTRACT

Utilities (e.g., apparatuses, systems, methods, etc.) for reducing or eliminating gaps between the tips of male pins and the bottoms of corresponding female sockets of interfaced connectors (e.g., daughtercard and backplane connectors) of a computing module and a backplane of a server enclosure under a variety of differing mechanical tolerances in the lengths of the server enclosure and the computing module (e.g., along a dimension that is parallel to the longitudinal axes of the male pins and female sockets). The disclosed utilities allow for increased signal quality and data rates through interfaced connectors while reducing strain on the PCB, solder joints, and the like during the interfacing of the connectors.

CROSS REFERENCE TO RELATED APPLICATION

This application is a divisional of U.S. patent. Ser. No. 15/086,386,entitled “SYSTEM FOR ELECTRICAL CONNECTION OF PRINTED CIRCUIT BOARDS ANDBACKPLANES IN SERVER ENCLOSURE,” and filed on Mar. 31, 2016, theentirety of which is incorporated herein by reference as if set forth infull.

BACKGROUND 1. Field of the Invention

The present invention generally relates to computing devices such asservers and, more particularly, to the electrical connection of printedcircuit boards of a server with a backplane of the server.

2. Relevant Background

As generally referred to in the art, a server is a computing device thatis configured to perform operations for one or more other computingdevices connected over a network. For an entity that requires computinginfrastructure for handling relatively large amounts of network data, itis desirable to use servers that are designed to promoteorganizational/space efficiency and operational performance. In thisregard, some servers are designed to be arranged in a rack (e.g.,cabinet), where the rack may house numerous servers that are slidablyreceived into respective bays of the rack via pairs of rail members.

One type of server includes an enclosure (e.g., housing) having a numberof bays or sockets for slidably receiving a number of modules (e.g.,blades, field replaceable units (FRUs), etc.). For instance, each modulemay generally include a chassis (e.g., tray) containing a printedcircuit board (“PCB,” e.g., daughtercard) that includes any appropriatearrangement of processors, memory, storage, network connections, and thelike. One or more connectors (e.g., daughtercard connectors) that areelectrically connected to the PCB of each module may be configured toelectrically interface (e.g., mate) with one or more correspondingconnectors of a backplane (e.g., or midplane) of the server enclosure asthe module is inserted into a socket of the chassis. The backplane(e.g., which may include or be associated with any appropriate systemcontroller or manager) may provide non-core computing services toinstalled modules such as power, cooling, interconnects, management, andthe like.

SUMMARY

The server enclosure and modules inserted therein have variousmechanical tolerances. In the case of the server enclosure, there may bea mechanical tolerance in the distance from the front of the serverenclosure (e.g., adjacent to where a handle of a module interconnects)to the backplane connectors. In the case of the module, there may be amechanical tolerance in the distance from the front of the module (e.g.,adjacent to the handle) to the rear of the modules adjacent thedaughtercard connectors. These mechanical tolerances are typically takenup by allowing for variable “wipe” or variation in the length or degreeof overlap of the contacts of each respective pair of backplane anddaughtercard connectors. Specifically, one of the daughtercard andbackplane connectors includes a plurality of male pins while the otherof the daughtercard and backplane connectors includes a correspondingplurality of female sockets that are configured to receive the pluralityof male pins when the two connectors are interfaced. Thus, the abovemechanical tolerances of the server enclosure and modules insertedtherein are sometimes taken up by allowing the tip of each male pin tonot necessarily need to sit at the bottom of the corresponding femalesocket. However, the resulting gap between the tip of the male pin andthe bottom of the female socket allows the pin to serve as a resonatorand degrade the signal propagation thus causing unacceptable signaldegradation, especially at high data rates.

In this regard, disclosed herein are utilities (e.g., apparatuses,systems, methods, etc.) that are configured to reduce or eliminate suchgaps (e.g., so that this is substantially a “zero” gap) between the tipsof male pins and the bottoms of corresponding female sockets indaughtercard and backplane connectors in a wide variety of matingconditions to allow the connectors to provide higher signal quality athigher data rates. In the case where the length between the front of theserver enclosure and the backplane is at its longest (e.g., length plusits tolerance) and the length of the module from its front to its rearis at its shortest (e.g., length minus its tolerance), the disclosedutilities are configured to provide an insertion force against the PCBtowards the backplane so that the tips of the male pins just interfacewith the bottoms of the female sockets of the daughtercard and backplaneconnectors (e.g., with substantially zero gap between the male pin tipsand female socket bottoms). In the case where the length between thefront of the server enclosure and the backplane is at its shortest(e.g., length minus its tolerance) and the length of the module from itsfront to its rear is at its longest (e.g., length plus its tolerance),the disclosed utilities are configured to allow the PCB of the module toslide away from the backplane to prevent or limit damage to thebackplane, solder joints, and the like due to the “extra” length of themodule while still maintaining substantially zero gap between the malepin tips and female socket bottoms.

As will be discussed, the daughtercard (or other PCB to which thecorresponding daughtercard connectors are secured) of a module forinsertion into a server enclosure may be slidably mounted relative tothe module chassis along a direction or axis of travel (where thedirection of travel is parallel to the longitudinal axes of the malepins and the female sockets of the connectors) by way of a slidingsupport frame that is slidable over a bottom of the chassis. Thedaughtercard and connectors may be secured over or to the sliding framein any appropriate manner (e.g., so as to be non-movable relative to thesliding frame).

Initially, the rear portion of the module may be inserted into acorresponding socket of the server enclosure towards the backplane andany appropriate lever handle(s) movably secured to the front portion ofthe module chassis may contact a corresponding portion of the serverchassis and be pivoted or otherwise moved into a closed position todrive the daughtercard connectors into engagement with the backplaneconnectors. In the event closing of the handle(s) would otherwise leavethe tips of the male pins short of the bottom of the female sockets ofthe connectors, a biasing apparatus interconnected between the moduleand the sliding frame is configured to generate an insertion force thatovercomes any friction between the daughtercard and backplane connectorsand thus urges the sliding frame and thus the daughtercard connectors ina first direction relative to the module chassis further towards thebackplane so that the male pins just rest against the bottom of thefemale sockets of the connectors (e.g., substantially free of excessstrain on solder joints, the backplane, etc.).

In the event closing of the handle(s) drives the tips of the male pinsforcibly against the bottoms of the female sockets (or vice versa) ofthe connectors to an amount that would otherwise cause damage to themodule or server (e.g., to solder joints, daughtercard, backplane,etc.), the biasing apparatus allows the sliding frame and thus thedaughtercard connectors to move in an opposite second direction relativeto the module chassis towards the front portion of the chassis so thatthe male pins just rest against the bottom of the female sockets of theconnectors (e.g., substantially free of excess strain on solder joints,the backplane, etc.). Stated differently, the biasing apparatus isconfigured to reduce the force in the system by deflecting and allowingthe sliding frame to slide relative to the chassis rather thanoverstressing and damaging the backplane and the daughtercard due tomechanical interference.

In one aspect disclosed herein, a module for slidable receipt in anelectronics enclosure includes a chassis including opposite front andrear portions, opposite first and second side portions, and an interiorportion; a PCB mounted within the interior portion of the chassis forsliding movement along an axis that extends from the front portion tothe rear portion between the first and second side portions of thechassis; at least a first connector electrically connected to the PCBadjacent the rear portion of the chassis; and a biasing apparatusinterconnected between the chassis and the PCB that is configured todeflect upon engagement between the first connector and a correspondingsecond connector secured within the electronics enclosure as the chassisis inserted into a socket of the electronics enclosure.

In one embodiment, the chassis may further include a bottom portion,where the PCB is slidable over the bottom portion of the chassis alongthe axis. The module may also further include a frame that is slidablyattached to the bottom portion of the chassis for sliding movement alongthe axis, where the PCB is rigidly attached to the frame for movementtherewith along the axis. For instance, the biasing apparatus may have aspring constant less than that of the frame. In one arrangement, one ofthe frame and the chassis may include a plurality of protrusions and theother of the frame and the chassis includes a plurality of slots thatare configured to receive the plurality of protrusions to guide slidingof the frame and PCB along the axis.

In another aspect disclosed herein, a server includes an enclosureincluding a housing and an interior space within the housing, whereinthe interior space defines a plurality of sockets; a backplane securedto the housing within the interior space adjacent a rear portion of theplurality of sockets, where the backplane includes at least onebackplane connector adjacent the rear portion of each socket of theplurality of sockets; and a computing module receivable in a firstsocket of the plurality of sockets. The computing module includes achassis that is slidable within the first socket along a first axis; aPCB that is slidable relative to the chassis along a second axis that iscollinear with or parallel to the first axis; and a PCB connectorattached to the PCB for electrical connection with the backplaneconnector of the first socket.

In a further aspect disclosed herein, a method includes inserting achassis of a computing module into a socket of an enclosure;establishing, during the inserting, contact between a first electricalconnector of the chassis and a second electrical connector adjacent arear of the socket in the enclosure; and allowing the first electricalconnector to slide relative to the chassis during the establishing.

Any of the embodiments, arrangements, or the like discussed herein maybe used (either alone or in combination with other embodiments,arrangement, or the like) with any of the disclosed aspects. Merelyintroducing a feature in accordance with commonly accepted antecedentbasis practice does not limit the corresponding feature to the singular.Any failure to use phrases such as “at least one” does not limit thecorresponding feature to the singular. Use of the phrase “at leastgenerally,” “at least partially,” “substantially” or the like inrelation to a particular feature encompasses the correspondingcharacteristic and insubstantial variations thereof. Furthermore, areference of a feature in conjunction with the phrase “in oneembodiment” does not limit the use of the feature to a singleembodiment.

In addition to the exemplary aspects and embodiments described above,further aspects and embodiments will become apparent by reference to thedrawings and by study of the following descriptions.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a server including a number of computingmodules inserted into sockets of an enclosure according to oneembodiment.

FIG. 2 is a perspective view of the server of FIG. 1 with one of thecomputing modules being removed from its socket of the enclosure.

FIG. 3 is a perspective view of a backplane of the server enclosure ofFIG. 1.

FIG. 4 is a perspective view of the backplane of FIG. 3 including firstand second computing modules interfaced therewith.

FIG. 5 is a front perspective view of the first computing module of FIG.4.

FIG. 6 is an exploded front perspective view of the first computingmodule of FIG. 4.

FIG. 7 is a rear perspective view of the first computing module of FIG.4.

FIG. 8 is an exploded rear perspective view of the first computingmodule of FIG. 4.

FIG. 9 is a rear perspective view of the first computing module of FIG.4 with a top cover and PCB being removed to illustrate a sliding frameand biasing apparatus.

FIG. 10 is a close-up perspective view of the sliding frame and biasingapparatus of FIG. 9.

FIG. 11 is a close-up perspective view of a portion of the sliding frameof FIG. 10.

FIG. 12 is a front perspective view of the second computing module ofFIG. 4.

FIG. 13 is an exploded front perspective view of the second computingmodule of FIG. 4.

FIG. 14 is a rear perspective view of the second computing module ofFIG. 4.

FIG. 15 is an exploded rear perspective view of the second computingmodule of FIG. 4.

FIG. 16 is a rear perspective view of the second computing module ofFIG. 4 with a top cover and PCB being removed to illustrate a slidingframe and biasing apparatus.

FIG. 17 is a close-up perspective view of the sliding frame and biasingapparatus of FIG. 16.

FIG. 18 is a close-up perspective view of a portion of the sliding frameof FIG. 17.

FIG. 19 is a close-up perspective view of the rear portion of the secondcomputing module of FIG. 4 and illustrating a stiffening system forrigidly interconnecting the plurality of connectors.

FIG. 20 is a perspective view similar to FIG. 19 but with the stiffeningbuttress interconnected to the plurality of connectors.

FIG. 21 is another perspective view similar to FIG. 20 but including aplurality of beam members interconnecting the stiffening buttress to thePCB.

FIG. 22 is a close-up perspective view of a portion of FIG. 21.

DETAILED DESCRIPTION

Disclosed herein are utilities (e.g., apparatuses, systems, methods,etc.) for reducing or eliminating gaps between the tips of male pins andthe bottoms of corresponding female sockets of interfaced connectors(e.g., daughtercard and backplane connectors) of a computing module anda backplane of a server enclosure under a variety of differingmechanical tolerances in the lengths of the server enclosure and thecomputing module (e.g., along a dimension that is parallel to thelongitudinal axes of the male pins and female sockets). The disclosedutilities allow for increased signal quality and data rates throughinterfaced connectors while reducing strain on the PCB, solder joints,and the like during the interfacing of the connectors.

Turning initially to FIGS. 1-4, various views of a server 100 that isconfigured to incorporate the connector gap-reducing utilities disclosedherein according to one embodiment are illustrated. The server 100generally includes a server enclosure 104 (e.g., electronics enclosure)including a housing 108 (e.g., chassis) having an interior space 112that defines a plurality of sockets 116 for receiving a respectiveplurality of computing modules 200. The housing 108 of the serverenclosure 104 generally includes a front portion 120 and an oppositerear portion 124, where each computing module 200 is configured to beinitially received into one of the sockets 116 via the front portion 120of the housing 108. Thereafter, the computing module 200 may be slidwithin the socket 116 towards the rear portion 124 of the housing untilthe computing module 200 electrically interfaces with a backplane 300 ofthe server 100 that is mounted within the interior space 112 adjacentthe rear portion 124.

With reference to FIG. 3, the backplane 300 may include a chassis 304(e.g., housing) and a PCB 308 attached to the chassis 304 that includesany appropriate number and type of connectors 312 that are configured tobe electrically interfaced with corresponding connectors of thecomputing modules 200. For instance, a plurality of rows of connectors312 may be appropriately arranged along the PCB 308, where each row ofconnectors 312 is configured to be situated adjacent a rear portion of arespective one of the sockets 116 when the backplane 300 isappropriately mounted within the housing 108 of the server enclosure104. The backplane 300 is thus broadly configured to serve as acomputing bus that appropriately interconnects the computing modules 200to each other, to other networks, and the like.

Each computing module 200 broadly includes a chassis 204 (e.g., housing)including opposite front and rear portions 208, 212 and containing anyappropriate arrangement of processors, memory, storage, and the likethat are collectively configured to handle any appropriate number andtype of workloads such as database, applications, and the like. Thechassis 204 may have a form factor that allows the chassis 204 to beslidably received along an axis 400 into one of the sockets 116 of theserver enclosure 104. The axis 400 of each socket 116 may generallyextend from the front portion 120 of the housing to the rear portion 124of the housing. With reference to FIG. 2, each computing module 200 mayalso include any appropriate insertion force generation apparatusconfigured to provide a particular amount of force along or parallel tothe axis 400 for electrically interfacing connectors adjacent the rearof the chassis 204 and the corresponding connectors 312 on the backplane300 (e.g., by way of overcoming friction forces between the respectivepairs of connectors).

For instance, the insertion force generation apparatus may be in theform of first and second levers 216 ₁, 216 ₂ that are attached to thechassis 204 for pivotal movement about respective pivot axes 220 ₁, 220₂ adjacent opposite sides of the front portion 208 between openpositions (e.g., as shown in FIG. 2) and closed positions (e.g., asshown in FIG. 1). A user may initially insert the rear portion 212 ofthe chassis 204 of a computing module 200 into a particular socket 116of the server enclosure 104 (with the levers 216 in their openpositions) and continue insertion of the chassis 204 along the axis 400until initial resistance between the connectors adjacent the rear of thechassis 204 and the connectors 312 of the backplane 300 is encountered(which corresponds with the levers 216 and the front portion 208 of thechassis generally aligning with the front portion 120 of the serverenclosure 104). As the user thereafter pushes handle portions 224 ₁, 224₂ of each lever 216 ₁, 216 ₂ about the respective pivot axes 220 ₁, 220₂, catch portions 228 ₁, 228 ₂ of each lever 216 ₁, 216 ₂ catch oncorresponding portions of the housing 108 of the server enclosure 104which drives the chassis 204 further along the axis 400 (e.g., so thatthe connectors of the computing module 200 and the connectors 312 of thebackplane 300 further engage with each other) as the user pushes thehandle portions 224 ₁, 224 ₂ into their closed positions.

FIGS. 5-8 present various views of a first computing module 200 ₁ of thenumber of computing modules 200 of the server 100. The chassis 204 mayinclude a base member 232 (e.g., tray) having a base surface 236 as wellas first and second opposite walls 240 ₁, 240 ₂ extending upwardly awayfrom the base surface 236. The chassis 204 may also include a covermember 248 that is configured to be disposed over the first and secondopposite walls 240 ₁, 240 ₂ across the base surface 236 of the basemember 232. The base surface 236 and first and second opposite walls 240₁, 240 ₂ (and cover member 248 if included) generally define an interiorportion 244 of the chassis 204 for containing a PCB 252 (e.g.,daughtercard). The PCB 252 generally includes a front portion 253 thatis configured to be disposed adjacent the front portion 208 of thechassis 204, an opposite rear portion 254 that is configured to bedisposed adjacent the rear portion 212 of the chassis 204, and anyappropriate arrangement of electrical components (e.g., processors,memory, controllers, etc. interconnected by conductive traces). Aplurality of connectors 256 are electrically connected to the conductivetraces of the PCB 252 adjacent the rear portion 252 of the PCB 252 forelectrical interfacing (e.g., mating) with the corresponding pluralityof connectors 312 of the backplane 300 adjacent the rear portion of aparticular one of the sockets 116 of the server enclosure 104.

The PCBs (and thus connectors) attached thereto of computing modules ofexisting servers are typically rigidly or otherwise non-movably attachedto the chassis of the computing modules. Using FIG. 8 as an example, thePCB 252 would be rigidly attached to or relative to the base surface 236of the chassis 204 in such that the PCB 252 and connectors 256 would notbe able to move relative to the chassis 204. However, such anarrangement would limit the ability of the connectors 256 of the PCB 252to be able to fully mate with the connectors 312 of the backplane 300(e.g., so that the ends or tips of the male pins of one of theconnectors 256, 312 rest flush with the bottoms of the female sockets ofthe other of the connectors 256, 312) under a wide range of mechanicaltolerances in the lengths of the chassis 204 (the distance between thefront and rear portions 208, 212) and the socket 116 (the distancebetween the front portion 120 of the housing 108 and the connectors 312of the backplane 300) free of bending of the PCBs 252, 308, damage tosolder joints, and the like.

In this regard, the PCB 252 and connectors 256 of the computing module200 ₁ are movably attached to the base member 232 of the chassis 204 sothat the PCB 252 and connectors 256 can move relative to the chassis 204as the connectors 256 are being interfaced with the connectors 312 ofthe backplane to allow the connectors 256 of the PCB 252 to be able tofully mate with the connectors 312 of the backplane 300 (for increasedsignal quality and data rates through the connectors 256, 312) under awide range of mechanical tolerances in the lengths of the chassis 204and the socket 116 within which the chassis 204 is receivedsubstantially free of bending of the PCBs 252, 308, damage to solderjoints, and the like. More specifically, the PCB 252 is mounted to orover the base surface 236 of the chassis 204 for sliding movement alongor relative to an axis 272 that is parallel to the axis 400 along whichthe chassis 204 slides as it is being inserted into the socket 116 ofthe server enclosure 104. Furthermore, at least one biasing apparatus500 interconnects the PCB 252 to the chassis 204 for applying a forceagainst the PCB 252 in a first direction along the axis 272 away fromthe front portion 208 of the chassis so that the connectors 256 cansubstantially fully mate with the corresponding connectors 312 of thebackplane 300 (e.g., male pins seated at bottom of female sockets). Theat least one biasing apparatus 500 is also configured to receive areaction force from the backplane connectors 312 that allows the PCB 252to move in an opposite second direction along the axis 272 towards thefront portion 208 while maintaining substantially full mating of theconnectors 256, 312 (e.g., in the event the particular lengths of thechassis 204 and enclosure socket 116 would otherwise result in damage tothe PCBs 252, 308, solder joints, etc. upon closing of the levers 116).

In one embodiment, and with reference to FIGS. 9-11, the PCB 252 (withconnectors 256 rigidly mounted thereto) may be rigidly mounted to asupport frame 260 that is mounted to or over the base surface 236 of thechassis 204 for sliding movement in first and second opposite directionsalong the axis 272 in any appropriate manner. In other words, the PCB252 and connectors 256 are mounted to be non-movable relative to theframe member 260 so that the support frame 260, PCB 252, and connectors256 move along the axis 272 simultaneously. For instance, the supportframe 260 may be in the form of a plurality of frame members 264 thatare appropriately rigidly attached to each other (and thus non-movablerelative to each other) and that are collectively configured to supportthe PCB 252 across a substantial entirety of a length and width of thePCB 252. The PCB 252 may be rigidly mounted or attached to the supportframe 260 (e.g., so that the support frame 260 is disposed between thebase surface 236 and the PCB 252) in any appropriate manner. As just oneexample, the support members 264 may include a plurality of apertures268 therein that are configured to align with corresponding apertures(not labeled) in the PCB for receipt of any appropriate fastenerstherethrough that are collectively configured to inhibit movement of thePCB 252 relative to the support frame 260 (PCB 252 not shown in FIGS.9-11 in the interest of clarity). The support frame 260 may also takevarious other forms such as a plate, spaced members that are notattached to each other but that are nevertheless non-movable relative toeach other, and/or the like.

The support frame 260 may be mounted for sliding movement in first andsecond directions along or parallel to the axis 272 in any appropriatemanner. As just one example, the base surface 236 may include aplurality of protrusions 276 extending upwardly (e.g. perpendicularly)therefrom while the support frame 260 may include a plurality ofcorresponding slots 280 that are configured to receive the plurality ofprotrusions 276. A longitudinal axis of each of the slots 280 may beparallel to the axis 272 so that the respective pairs of protrusions 276and slots 280 collectively guide sliding movement or translation of thesupport frame 260 (and PCB 252 and connectors 256 mounted thereto) alongthe axis 272. To facilitate mounting of the support frame 260 over thebase surface 236 for sliding movement relative thereto along the axis272, each slot 280 may be in the form of a keyhole having an enlargedopening 282 that is configured to receive an enlarged head 284 of theprotrusion 276, as well as a narrowed portion 283 along which theenlarged head 284 is configured to slide.

Thus, the enlarged openings 282 of the support frame 260 may beinitially aligned and pressed over the enlarged heads 284 of theprotrusions of the base surface 236. The support frame may then be slidalong the axis 272 towards the front portion 208 of the chassis 204 tobring the enlarged heads 284 into the narrowed portions 283 of the slots280. See FIGS. 10-11. While the protrusions 276 are illustrated as beingattached to or extending from the base surface 236 and the slots 280 aredisposed in the support frame 260, the arrangement could be vice versaso that the protrusions 276 extend downwardly away from a bottom surfaceof the support frame 260 and the slots 280 are disposed in the basesurface 236. Furthermore, various other manners of slidably attachingthe support frame 260 to or relative to the base surface 236 areenvisioned and encompassed herein.

With continued reference to FIGS. 9-11, the at least one biasingapparatus 500 (e.g., any appropriate spring member(s)) may in oneembodiment be in the form of first and second biasing apparatuses 500 ₁,500 ₂, each having at least one first portion 504 that is rigidlyattached to or relative to the chassis 204 (so as to be non-movablerelative to the chassis 204), at least one second portion 508 that isrigidly attached to or relative to the frame member 260 (so as to benon-movable relative to the frame member 260), and at least one thirdportion 512 (e.g., arm, member, etc.) between a respective pair of firstand second portions 504, 508 that is configured to deflect as theconnectors 256 of the PCB 252 engage with the connectors 312 of thebackplane 300 when the chassis 204 is inserted into the socket 116 ofthe server enclosure 104 as discussed in more detail below. The firstand second portions 504, 508 may be respectively rigidly attached to thebase surface 236 and support frame 260 in any appropriate manner (e.g.,one or more fasteners 516, 520 such as rivets or the like).

In one arrangement, each of the first and second biasing apparatuses 500₁, 500 ₂ may be in the form of a beam spring whereby the at least onethird portion 512 is configured to bend in a plane generally parallel tothe base surface 236 during engagement between the connectors 256 of thePCB 252 and the connectors 312 of the backplane 300. In the specificarrangement shown in FIG. 10, each of the first and second biasingapparatuses 500 ₁, 500 ₂ may include a pair of second portions 508 and apair of third portions 512 that are disposed on opposite sides of thefirst portion 504. In this regard, each of the first and second biasingapparatuses 500 ₁, 500 ₂ may be in the form of first and second beamsprings that extend in opposite directions (e.g., where the thirdportions 512 may extend generally perpendicularly to the axis 272).

In operation, the support frame 260 and PCB 252 (with connectors 256rigidly attached to PCB 252 as discussed previously) may be slidablymounted within the base member 232 of the chassis 204 of a computingmodule 200 and the at least one biasing apparatus 500 may beinterconnected between the chassis 204 and the support frame 260 asdiscussed above. For instance, the slots 280/protrusions 276 of thesupport frame 260 may be aligned with the slots 280/protrusions 276 ofthe base surface 236 and disposed thereover. Furthermore, the firstportions 504 of the first and second biasing apparatuses 500 ₁, 500 ₂may be rigidly secured to the base surface 236 and the second portions508 of the first and second biasing apparatuses 500 ₁, 500 ₂ may berigidly secured to the support frame 260 as discussed above or in otherappropriate manners. The PCB 252 and connectors 256 may then be securedto the support frame 260. It is to be understood that the frame member260, PCB 252 and connectors 256, and biasing apparatus(es) 500 may besecured and/or interconnected in an order different than that discussedabove without departing from the scope of the present disclosure.

In any case, the cover 248 may then be secured over the base member 232to contain the PCB 252 within the chassis 204 and the entire firstcomputing module 200 ₁ may be inserted into one of the sockets 116 ofthe server enclosure 104 along an axis 400 within the socket 116 (e.g.,similar to how second computing module 200 ₂ of FIG. 2 may be insertedinto one of the sockets 116 along axis 400, where the connectors 156 ofthe PCB 252 are disposed adjacent the rear portion 212 and face awayfrom the front portion 208 for interfacing with the connectors 312 ofthe backplane 300). Once the first computing module 200 ₁ has beensubstantially inserted into the socket 116, the first and second levers216 ₁, 216 ₂ (or other force generation apparatus) may be appropriatelyclosed or otherwise manipulated as discussed previously to drive theconnectors 256 of the PCB 252 into the connectors 312 of the backplane300.

At some point before the ends of the male pins of one of the connectors256 or connectors 312 reach the bottom of the female sockets of theother of the connectors 256 or connectors 312, friction between the malepins and female sockets urges the sliding frame 260, PCB 252 andconnectors 256 along or parallel to the axis 272 towards the frontportion 208 of the chassis 204 which deflects and compresses the firstand second biasing apparatuses 500 ₁, 500 ₂. With reference to FIG. 10,for instance, the frame member 260 and second portions 508 of the firstand second biasing apparatuses 500 ₁, 500 ₂ may be moved along the axis272 towards the front portion 208 of the chassis 204 which deflects andbends the third portions 512 by a first amount (e.g., where the secondand third portions 508, 512 slide over the base surface 236). Suchdeflection of the first and second biasing apparatuses 500 ₁, 500 ₂generates an insertion force on the frame member 260 along or parallelto the axis 272 away from the front portion 208 that overcomes thefriction between the male pins and female sockets of the connectors 256,312 so that the ends of the male pins come to rest just flush at thebottom of the female sockets. This scenario may arise when the length ofthe chassis 204 (the distance between the front and rear portions 204,208) is less than the length of the socket 116 (the distance between thefront portion 120 of the server enclosure 104 and the PCB 308 of thebackplane 300).

In the event the length of the chassis 204 (the distance between thefront and rear portions 204, 208) is greater than the length of thesocket 116 (the distance between the front portion 120 of the serverenclosure 104 and the PCB 308 of the backplane 300) such that thebackplane 300, PCB 252, and/or the like would otherwise be stressed ordamaged, the biasing apparatus 500 (e.g., the first and second biasingapparatuses 500 ₁, 500 ₂) receives a reaction force from the backplaneconnectors 312 (via the support frame 260) and compresses or deflects bya second amount greater than the first amount towards the front portion208 of the chassis which allows the PCB 252 and connectors 256 to movealong the axis 272 relative to the chassis 204 towards the front portion208 of the chassis 204. Various parameters of the biasing apparatus(es)500, the support frame 260, etc. (e.g., such as spring constants,stiffnesses, dimensions, etc.) can be appropriately selected so that themale pins of one of the connectors 256, 312 just rest flush at thebottom of the female sockets of the other of the connectors 256, 312under a wide range of mechanical tolerances in the lengths of thechassis 204 and the socket 116 free of bending of the PCBs 252, 308,damage to solder joints, and the like (e.g., based on the particulartypes of connectors 256, 312, the amount of insertion force generated bylevers 216 or other insertion force generation apparatus, and the like).

FIGS. 12-15 present various views of a second computing module 200 ₂ ofthe number of computing modules 200 of the server 100. Like the firstcomputing module 200 ₁, the second computing module 200 ₂ may include abase member 232 (e.g., tray) having a base surface 236 with first andsecond opposite walls 240 ₁, 240 ₂ extending upwardly away from the basesurface 236 and a cover member 248 that is configured to be disposedover the first and second opposite walls 240 ₁, 240 ₂ across the basesurface 236 of the base member 232. The base member 232 and cover member248 generally define an interior portion 244 for containing a PCB 252(e.g., daughtercard) including a front portion 253 that is configured tobe disposed adjacent the front portion 208 of the chassis 204, anopposite rear portion 254 that is configured to be disposed adjacent therear portion 212 of the chassis 204, and any appropriate arrangement ofelectrical components (e.g., processors, memory, controllers, etc.interconnected by conductive traces).

A plurality of connectors 256 are electrically connected to theconductive traces of the PCB 252 adjacent the rear portion 252 of thePCB 252 for electrical interfacing (e.g., mating) with the correspondingplurality of connectors 312 of the backplane 300 adjacent the rearportion of a particular one of the sockets 116 of the server enclosure104. The arrangement of electrical components on the PCB 252 as well asthe dimensions of the PCB 252 of the second computing module 200 ₂ maybe the same as or different than that on the PCB 252 of the firstcomputing module 200 ₁. Furthermore, the connectors 256 on the PCB 252of the second computing module 200 ₂ may be the same as or differentthan those on the PCB 252 of the first computing module 200 ₁ (e.g., solong as they are configured to interface with the connectors 312 of thebackplane 300 at the rear of the particular socket 116 into which thesecond computing module 200 ₂ is to be inserted). In one arrangement, anapparatus 600 (e.g., plate, frame) may be appropriately secured over atop of the PCB 252 for use in insulating and/or increasing the rigiditythereof.

With additional reference now to FIGS. 16-18, the PCB 252 (withconnectors 256 rigidly mounted thereto) may be rigidly mounted to asupport frame 260′ that is mounted to or over the base surface 236 ofthe chassis 204 for sliding movement in first and second oppositedirections along the axis 272 in any appropriate manner. For instance,the support frame 260′ may be in the form of a plurality of framemembers 264 that are appropriately rigidly attached to each other (andthus non-movable relative to each other) and that are collectivelyconfigured to support the PCB 252 across a substantial entirety of alength and width of the PCB 252. The PCB 252 may be rigidly mounted orattached to the support frame 260′ (e.g., so that the support frame 260is disposed between the base surface 236 and the PCB 252) in anyappropriate manner (e.g. via apertures (not labeled) in the supportframe 260′). The support frame 260′ may also take various other formssuch as a plate, spaced members that are not attached to each other butthat are nevertheless non-movable relative to each other, and/or thelike. The support frame 260′ may be mounted for sliding movement infirst and second directions along or parallel to the axis 272 such asvia protrusions 276 and slots 280 as discussed in relation to thesupport frame 260 of the first computing module 200 ₁ or in otherappropriate manners.

The at least one biasing apparatus 500′ (e.g., any appropriate springmember(s)) may have one or more first portions 504′ that are rigidlyattached to or relative to the chassis 204 (so as to be non-movablerelative to the chassis 204, such as via fasteners/rivets 516′ or thelike), one or more second portions 508′ that are in contact with theframe member 260′, and one or more third portions 512′ (e.g., arms,members, etc.) disposed between respective pairs of first and secondportions 504′, 508′ that are configured to deflect as the connectors 256of the PCB 252 engage with the connectors 312 of the backplane 300 whenthe chassis 204 is inserted into the socket 116 of the server enclosure104. For instance, the second and third portions 508′, 512′ may beconfigured to bend or deflect in a plane generally parallel to the basesurface 236 during engagement between the connectors 256 of the PCB 252and the connectors 312 of the backplane 300. In one arrangement, thesupport frame 260′ and/or the second portions 508′ of the biasingapparatus 500′ may include one or more force concentration portions 524to facilitate bending (e.g., flexing, deflection) of the second andthird portions 508′, 512′. As shown in FIG. 17, for instance, the forceconcentration portions 524 may be in the form of protrusions (e.g.,bumps) extending away from a top edge of the support frame 260′ towardsthe second portions 508′ for contact therewith.

In operation, the support frame 260′, PCB 252 and biasing apparatus 500′of the second computing module 200 ₂ may be interconnected into thechassis 204 in any appropriate manner consistent with the abovediscussion and the cover 248 may be secured over the base member 232 tocontain the PCB 252 within the chassis 204. The entire second computingmodule 200 ₂ may be inserted into one of the sockets 116 of the serverenclosure 104 along an axis 400 within the socket 116 (e.g., see secondcomputing module 200 ₂ in FIG. 2). Once the second computing module 200₂ has been substantially inserted into the socket 116, the first andsecond levers 216 ₁, 216 ₂ (or other force generation apparatus) may beappropriately closed or otherwise manipulated as discussed previously todrive the connectors 256 of the PCB 252 into the connectors 312 of thebackplane 300.

At some point before the ends of the male pins of one of the connectors256 or connectors 312 reach the bottom of the female sockets of theother of the connectors 256 or connectors 312, friction between the malepins and female sockets urges the support frame 260′, PCB 252 andconnectors 256 along or parallel to the axis 272 towards the frontportion 208 of the chassis 204 which deflects and compresses the biasingapparatus first and second portions 508′, 512′ of the biasing apparatus500′ by a first amount. Such deflection of the biasing apparatuses 500′generates an insertion force on the frame member 260′ along or parallelto the axis 272 away from the front portion 208 that overcomes thefriction between the male pins and female sockets of the connectors 256,312 so that the ends of the male pins come to rest just flush at thebottom of the female sockets. This scenario may arise when the length ofthe chassis 204 (the distance between the front and rear portions 204,208) is less than the length of the socket 116 (the distance between thefront portion 120 of the server enclosure 104 and the PCB 308 of thebackplane 300).

In the event the length of the chassis 204 (the distance between thefront and rear portions 204, 208) is greater than the length of thesocket 116 (the distance between the front portion 120 of the serverenclosure 104 and the PCB 308 of the backplane 300) such that thebackplane 300, PCB 252, and/or the like would otherwise be stressed ordamaged, the biasing apparatus 500′ (the second portions 508′) receivesa reaction force from the backplane connectors 312 (via the supportframe 260′) and compresses or deflects by a second amount greater thanthe first amount which allows the PCB 252 and connectors 256 to movealong the axis 272 relative to the chassis 204 towards the front portion208 of the chassis 204. Various parameters of the biasing apparatus500′, the support frame 260′, etc. (e.g., such as spring constants,stiffnesses, dimensions, etc.) can be appropriately selected so that themale pins of one of the connectors 256, 312 just rest flush at thebottom of the female sockets of the other of the connectors 256, 312under a wide range of mechanical tolerances in the lengths of thechassis 204 and the socket 116 free of bending of the PCBs 252, 308,damage to solder joints, and the like (e.g., based on the particulartypes of connectors 256, 312, the amount of insertion force generated bylevers 216 or other insertion force generation apparatus, and the like).

In some situations, the insertion force generated by the levers 216 orother insertion force generation apparatus may be above or below acenter height of the connectors 256 on the PCB 252 of one of thecomputing modules 200. As a result, bending moments may occur which canrock the connectors 256 back from the corresponding connectors 312 ofthe backplane 300 and thus inhibit full mating between the respectivepairs of connectors 256, 312. For instance, the respective pairs ofconnectors 256, 312 may be fully mated at the bottom thereof while a gapmay exist at the top thereof.

In this regard, and turning now to FIGS. 19-22, one or more of thecomputing modules 200 may include connector stiffening system 700 thatis configured to resist the above-discussed bending moments that mayotherwise occur due to discrepancies in the height of the generatedinsertion force and the center heights of the connectors 256. Broadly,the stiffening system 700 includes a stiffening plate 704 that isconfigured to be rigidly attached to and to interconnect the pluralityof connectors 256 on the PCB 252. For instance, the stiffening plate 704may be disposed over a top of the connectors 256 (e.g., such that theconnectors 256 are disposed between the stiffening plate 704 and the PCB252) and the stiffening plate 704 may be rigidly (e.g., non-movably)attached to the connectors 256 in any appropriate manner (e.g., such asvia inserting fasteners 705 through apertures (not shown) in thestiffening plate 704 and through corresponding aligned apertures 706 inor attached to the connectors 256).

The stiffening system 700 may also include a plurality of firststiffening members 708 that interconnect the stiffening plate 704 to thePCB 252 (or at least so as to be non-movable relative to the PCB 252)and a plurality of second stiffening members 712 that interconnect thestiffening plate 704 to the PCB 252 (or at least so as to be non-movablerelative to the PCB 252). The first stiffening members 708 (e.g.,brackets, beams, or other rigid pieces of material) may include a firstportion 709 that is rigidly (non-movably) attached to the stiffeningplate 704 in any appropriate manner (e.g., fasteners and alignedapertures) and an opposite second portion 710 that is rigidly(non-movably) attached to the PCB 252 or relative to the PCB 252 (e.g.,to stiffening apparatus 600, see FIGS. 13 and 15) in any appropriatemanner (e.g., fasteners and aligned apertures). For instance, the firststiffening members 708 may be disposed between adjacent connectors 256in a manner that allows airflow therethrough into fans of the server100.

The second stiffening members 712 (e.g., brackets, beams, or other rigidpieces of material) may include a first portion 713 that is rigidly(non-movably) attached to the stiffening plate 704 in any appropriatemanner (e.g., fasteners and aligned apertures) and an opposite secondportion 714 that is rigidly (non-movably) attached to the PCB 252 orrelative to the PCB 252 (e.g., to stiffening apparatus 600, see FIGS. 13and 15) in any appropriate manner (e.g., fasteners and alignedapertures). For instance, the second stiffening members 712 may bedisposed between the connectors 256 and the front portion 208 of thechassis 204 or in other words between the connectors 256 and thelocation from where the insertion force is being generated and applied.

With reference to FIGS. 21-22, an insertion force 800 (e.g., generatedby levers 216 or other insertion force generation apparatus) may bedirected along or parallel to axes 400, 272 (see FIGS. 2 and 16) formating the connectors 256 on the PCB 252 with the connectors 312 of thebackplane 300. As discussed above, the insertion force 800 can sometimesinduce bending moments in the connectors 256 as the connectors 256 matewith the connectors 312 of the backplane 300 which can create gaps atthe top or bottom of the connectors 256, 312 and thereby reduce signalquality through the connectors 256, 312. In the event that the insertionforce 800 is disposed at a height lower than the center height of theconnectors 256 (as measured from the PCB 252), the insertion force 800can generate a bending moment 810 in the connectors 256 that tends tomove the tops of the connectors 256 in a counterclockwise direction andthereby separate the tops of the connectors 256 from the tops of thecorresponding connectors 312 creating a gap therebetween.

In this regard, the stiffening system 700 is configured to resist oreven prevent or limit bending moments from being induced in theconnectors 256 that would otherwise prevent or limit the connectors 256from fulling mating with the connectors 312 (i.e., from the top to thebottom of the connectors 256, 312, e.g., such that the ends of all ofthe male pins just rest at the bottom of all of the corresponding femalesockets). For instance, the stiffening plate 704 and the secondstiffening members 712 may be configured resist the bending moment 810by providing an opposing reaction force 820 that is at least equal tothe bending moment to prevent or limit the tops of the connectors 256from pulling away from the tops of the connectors 312. In other words,the stiffening plate 704 and the second stiffening members 708 maytransmit connector insertion forces from the tops of the connectors 256to the PCB 252 (or to the stiffening apparatus 600).

In one arrangement, first and second attachment structures 830 ₁, 830 ₂may be rigidly attached to the support frame 260′ adjacent the first andsecond walls 240 ₁, 240 ₂ of the chassis 204 (so as to be non-movablerelative to the support frame 260′ and movable relative to the first andsecond walls 240 ₁, 240 ₂) for connection with the stiffening plate 704.For instance, each of the first and second attachment structures 830 ₁,830 ₂ may include one or more apertures 840 that are configured to alignwith corresponding apertures (not labeled) in the stiffening plate 704for receipt of fasteners 850 therethrough.

It will be readily appreciated that many additions and/or deviations maybe made from the specific embodiments disclosed in the specificationwithout departing from the spirit and scope of the invention. Theillustrations and discussion herein has only been provided to assist thereader in understanding the various aspects of the present disclosure.For instance, a server 100 may include a plurality of first computingmodules 200 ₁ and/or a plurality of second computing modules 200 ₂ forreceipt into respective sockets 116 of the server enclosure 104.

Furthermore, one or more various combinations of the above discussedarrangements and embodiments are also envisioned. For instance, thesupport frame 260 and biasing apparatus(es) 500 discussed in relation tothe first computing module 200 ₁ may be used in the second computingmodule 200 ₂ while the support frame 260′ and biasing apparatus 500′discussed in relation to the second computing module 200 ₂ may be usedin the first computing module 200 ₁.

While this specification contains many specifics, these should not beconstrued as limitations on the scope of the disclosure or of what maybe claimed, but rather as descriptions of features specific toparticular embodiments of the disclosure. Furthermore, certain featuresthat are described in this specification in the context of separateembodiments can also be implemented in combination in a singleembodiment. Conversely, various features that are described in thecontext of a single embodiment can also be implemented in multipleembodiments separately or in any suitable subcombination. Moreover,although features may be described above as acting in certaincombinations and even initially claimed as such, one or more featuresfrom a claimed combination can in some cases be excised from thecombination, and the claimed combination may be directed to asubcombination or variation of a subcombination.

Similarly, while operations are depicted in the drawings in a particularorder, this should not be understood as requiring that such operationsbe performed in the particular order shown or in sequential order, orthat all illustrated operations be performed, to achieve desirableresults. In certain circumstances, multitasking and/or parallelprocessing may be advantageous. Moreover, the separation of varioussystem components in the embodiments described above should not beunderstood as requiring such separation in all embodiments, and itshould be understood that the described program components and systemscan generally be integrated together in a single software and/orhardware product or packaged into multiple software and/or hardwareproducts.

The above described embodiments including the preferred embodiment andthe best mode of the invention known to the inventor at the time offiling are given by illustrative examples only.

We claim:
 1. A server, comprising: an enclosure including a housing andan interior space within the housing, wherein the interior space definesa plurality of sockets; a backplane secured to the housing within theinterior space adjacent a rear portion of the plurality of sockets,wherein the backplane includes at least one backplane connector adjacentthe rear portion of each socket of the plurality of sockets; and acomputing module receivable in a first socket of the plurality ofsockets, wherein the computing module includes: a chassis that isslidable within the first socket along a first axis; a printed circuitboard (PCB) that is slidable relative to the chassis along a second axisthat is collinear with or parallel to the first axis; and at least onePCB connector attached to the PCB for mating with the backplaneconnector of the first socket when the computing module is received inthe first socket, wherein the at least one PCB connector is a pluralityof PCB connectors electrically attached to the PCB, and wherein thecomputing module further includes: a stiffening plate interconnectingthe plurality of PCB connectors; and a plurality of stiffening membersinterconnecting the stiffening plate to the PCB, wherein the stiffeningplate and the plurality of stiffening members are configured resistbending moments induced in the plurality of PCB connectors as thecomputing module is inserted into the first socket of the enclosure; anda biasing apparatus interconnected between the chassis and the PCB thatis configured to allow the PCB to slide along the second axis when thechassis is inserted into the first socket along the first axis.
 2. Theserver of claim 1, wherein the computing module further includes a framethat is slidably attached to the chassis for movement along the secondaxis, wherein the PCB is rigidly attached to the frame for movementtherewith along the second axis.
 3. The server of claim 2, wherein oneof the frame and the chassis includes a plurality of protrusions, andwherein the other of the frame and the chassis includes a plurality ofslots that configured to receive the plurality of protrusions to guidesliding of the frame and PCB along the second axis.
 4. The server ofclaim 1, wherein the computing module further includes a lever armpivotally attached to the chassis that is configured to contact aportion of the enclosure as the lever arm pivots into a closed positionto urge the chassis into the first socket towards the backplane.
 5. Theserver of claim 1, wherein the at least one backplane connector includesone of a plurality of male pins or a plurality of corresponding femalesockets, and wherein the at least one PCB connector includes the otherof the plurality of male pins or the plurality of corresponding femalesockets that are configured to mate with the one of the plurality ofmale pins or the plurality of corresponding female sockets of the atleast one backplane connector when the computing module is received inthe first socket.
 6. A server, comprising: an enclosure including ahousing and an interior space within the housing, wherein the interiorspace defines a plurality of sockets; a backplane secured to the housingwithin the interior space adjacent a rear portion of the plurality ofsockets, wherein the backplane includes at least one backplane connectoradjacent the rear portion of each socket of the plurality of sockets;and a computing module receivable in a first socket of the plurality ofsockets, wherein the computing module includes: a chassis that isslidable within the first socket along a first axis; a printed circuitboard (PCB) that is slidable relative to the chassis along a second axisthat is collinear with or parallel to the first axis; at least one PCBconnector attached to the PCB for electrical connection with the atleast one backplane connector of the first socket; and a biasingapparatus interconnected between the chassis and the PCB that isconfigured to allow the PCB to slide along the second axis when thechassis is inserted into the first socket along the first axis.
 7. Theserver of claim 6, wherein the biasing apparatus is a beam spring thatis configured to deflect within a plane that is parallel to a bottomportion of the chassis.
 8. The server of claim 6, wherein the computingmodule further includes a lever arm pivotally attached to the chassisthat is configured to contact a portion of the enclosure as the leverarm pivots into a closed position to urge the chassis into the firstsocket towards the backplane.
 9. The server of claim 6, wherein thecomputing module further includes a lever arm pivotally attached to thechassis that is configured to contact a portion of the enclosure as thelever arm pivots into a closed position to urge the chassis into thefirst socket towards the backplane.
 10. The server of claim 6, whereinthe at least one PCB connector is a plurality of PCB connectorselectrically attached to the PCB, and wherein the computing modulefurther includes: a stiffening plate interconnecting the plurality ofPCB connectors; and a plurality of stiffening members interconnectingthe stiffening plate to the PCB, wherein the stiffening plate and theplurality of stiffening members are configured resist bending momentsinduced in the plurality of PCB connectors as the computing module isinserted into the first socket of the enclosure.
 11. The server of claim6, wherein the at least one backplane connector includes one of aplurality of male pins or a plurality of corresponding female sockets,and wherein the at least one PCB connector includes the other of theplurality of male pins or the plurality of corresponding female socketsthat are configured to mate with the one of the plurality of male pinsor the plurality of corresponding female sockets of the at least onebackplane connector when the computing module is received in the firstsocket.
 12. A server, comprising: an enclosure including a housing andan interior space within the housing, wherein the interior space definesa plurality of sockets; a backplane secured to the housing within theinterior space adjacent a rear portion of the plurality of sockets,wherein the backplane includes at least one backplane connector adjacentthe rear portion of each socket of the plurality of sockets; and acomputing module receivable in a first socket of the plurality ofsockets, wherein the computing module includes: a chassis that isslidable within the first socket along a first axis; a printed circuitboard (PCB) that is slidable relative to the chassis along a second axisthat is collinear with or parallel to the first axis; at least one PCBconnector attached to the PCB for electrical connection with the atleast one backplane connector of the first socket; a frame that isslidably attached to the chassis for movement along the second axis,wherein the PCB is rigidly attached to the frame for movement therewithalong the second axis; and a biasing apparatus interconnected betweenthe chassis and the PCB that is configured to allow the PCB to slidealong the second axis when the chassis is inserted into the first socketalong the first axis.
 13. The server of claim 12, wherein the biasingapparatus includes at least first and second portions, wherein the firstportion is rigidly secured to the chassis and is non-movable relative tothe chassis, and wherein the second portion is in contact with theframe.
 14. The server of claim 13, wherein the second portion is rigidlysecured to the frame and is non-movable relative to the frame, andwherein the biasing apparatus includes a third portion between the firstand second portions that is configured to deflect upon engagementbetween the first and second connectors as the chassis is inserted intothe socket of the electronics enclosure.
 15. The server of claim 12,wherein the computing module further includes a lever arm pivotallyattached to the chassis that is configured to contact a portion of theenclosure as the lever arm pivots into a closed position to urge thechassis into the first socket towards the backplane.
 16. The server ofclaim 12, wherein the at least one PCB connector is a plurality of PCBconnectors electrically attached to the PCB, and wherein the computingmodule further includes: a stiffening plate interconnecting theplurality of PCB connectors; and a plurality of stiffening membersinterconnecting the stiffening plate to the PCB, wherein the stiffeningplate and the plurality of stiffening members are configured resistbending moments induced in the plurality of PCB connectors as thecomputing module is inserted into the first socket of the enclosure. 17.The server of claim 12, wherein the at least one backplane connectorincludes one of a plurality of male pins or a plurality of correspondingfemale sockets, and wherein the at least one PCB connector includes theother of the plurality of male pins or the plurality of correspondingfemale sockets that are configured to mate with the one of the pluralityof male pins or the plurality of corresponding female sockets of the atleast one backplane connector when the computing module is received inthe first socket.